Cell-matrix interactions and the ordered deposition of basement membrane (BM) components are of major importance for the maintenance of tissue homeostasis in complex epithelia. This aspect was studied in vitro in a coculture system designed as an oral mucosa model. As crucial epithelial features the kinetics of proliferation, expression of site-specific keratins as well as integrin patterns in correlation to synthesis of BM components were assessed by immunohistochemistry and in situ hybridization. Comparison with non-cornified gingiva as tissue of origin revealed different stages of epithelial development, eventually leading to complete reconstruction within a time frame of 1-3 weeks. First, the initial activated stage up to 1 week was characterized by (a) high keratinocyte proliferation, (b) extended expression of the basal cell-specific keratin K5 and (c) a patchy pattern of the differentiation-specific keratins K4 and K13. Second, after 2 weeks the improvement of histoarchitecture correlated to (a) predominant K5 expression in the basal and (b) extension of K4 and K13 within the suprabasal cell compartment, (c) high expression of integrins alpha3 beta1 and alpha6 beta4 including their ligand laminin-5 and (d) accumulating deposition of basement membrane components. Third, virtually complete tissue normalization at 3 weeks was indicated by (a) restriction of K5 to the basal cell area, (b) regular suprabasal localization of K4 and K13, (c) polarization of integrins to basal and parabasal cells and (d) linear codistribution of collagen IV, "classical" laminin (-1 or -10) and laminin-5 underneath the basal cells. Thus, these organotypic cocultures represent relevant equivalents for non-keratinized oral mucosa with typical gingival differentiation features and in addition suitable models for preclinical trials such as prospective dental material testing.
To establish a three-dimensional in vitro test system mimicking the physiological situation of the oral cavity, organotypic co-cultures consisting of primary gingival cells on a collagen matrix with fibroblasts were generated. The histomorphological development after 7 and 14 d revealed close similarity with the non-keratinized gingiva epithelium. Furthermore, as epithelial specific markers synthesis and localization of keratins as well as the deposition of basement membrane components were assessed on frozen sections by immunofluorescence and keratin expression by in situ hybridization. Primary keratinocytes in conventional culture strained positive for keratin K14 and the mucosal differentiation-specific keratins K4 and K13, while primary fibroblasts, isolated from the same tissue source, and also some keratinocytes, were positive for vimentin. In organotypic co-cultures the keratinocytes formed a multilayered epithelium within 14 d containing basal cells and flattened cells in the uppermost layers. Comparable to native non-keratinized gingiva keratin 14 gene expression was clearly detectable in the basal cell compartment but showed extending immunolocalization. In addition, particularly at the early stage (7 d), basally located keratinocytes were also vimentin positive. According to morphological differentiation K4 and K13 were detectable in suprabasal position a the RNA and protein level. The major basement membrane constituents collagen type IV and laminin increased with time revealing first an interrupted and later a fully extended staining underneath the basal cells. Maintenance of basal cell function was further demonstrated by cell proliferation (BrdU incorporation) which was initially high (7 d) but declined towards the later stages (14-21 d). The results demonstrate i) that this co-culture system leads to a stratified surface epithelium with morphological and biochemical characteristics of the non-keratinized gingiva epithelium and ii) that a state of physiological tissue balance was reached, thus rendering a suitable model for tissue compatibility studies.
We employed topographical patterning to analyze early keratinocyte differentiation on top of microfabricated pillar arrays. Fibronectin immobilized on pillar "heads" yielded a nucleus-associated granular keratin 1 (K1) pattern in immortalized human gingival keratinocytes (IHGK) at pillar interspaces of 14 µm. Decreasing distances of 11and 8 µm revealed cytoplasmic extension of the early differentiation marker K1 on poly-(dimethylsiloxane) (PDMS) pillars. The most extensive cytoplasmic K1 protein distribution noted at the smallest pillar scale coincided with higher ratios of K1 mRNA gene transcription. These experiments suggest that early keratinocyte differentiation was governed by the topographical characteristics of the pillar pattern. Moreover, they form the basis to study cell functions such as differentiation in a defined topologically structured environment.
BackgroundMechano-transduction in periodontal ligament (PDL) cells is crucial for physiological and orthodontic tooth movement-associated periodontal remodelling. On the mechanistic level, molecules involved in this mechano-transduction process in PDL cells are not yet completely elucidated.ResultsIn the present study we show by western blot (WB) analysis and/or indirect immunofluorescence (IIF) that mechanical strain modulates the amount of the matrix metalloproteinase MMP-13, and induces non-coherent modulation in the amount and activity of signal transducing molecules, such as FAK, MAP-kinases p42/44, and p38 stress kinase, suggesting their mechanistic role in mechano-transduction. Increase in the amount of FAK occurs concomitant with increased levels of the focal contact integrin subunits β3 and β1, as indicated by WB or optionally by IIF. By employing specific inhibitors, we further identified p42/44 and p38 in their activated, i.e. phosphorylated state responsible for the expression of MMP-13. This finding may point to the obedience in the expression of this MMP as extracellular matrix (ECM) remodelling executioner from the activation state of mechano-transducing molecules. mRNA analysis by pathway-specific RT-profiler arrays revealed up- and/or down-regulation of genes assigning to MAP-kinase signalling and cell cycle, ECM and integrins and growth factors. Up-regulated genes include for example focal contact integrin subunit α3, MMP-12, MAP-kinases and associated kinases, and the transcription factor c-fos, the latter as constituent of the AP1-complex addressing the MMP-13 promotor. Among others, genes down-regulated are those of COL-1 and COL-14, suggesting that strain-dependent mechano-transduction may transiently perturbate ECM homeostasis.ConclusionsStrain-dependent mechano-/signal-transduction in PDL cells involves abundance and activity of FAK, MAP-kinases p42/44, and p38 stress kinase in conjunction with the amount of MMP-13, and integrin subunits β1 and β3. Identifying the activated state of p42/44 and p38 as critical for MMP-13 expression may indicate the mechanistic contribution of mechano-transducing molecules on executioners of ECM homeostasis.
Background: Regulation of bone remodeling during orthodontic tooth movement. Results: Tensile stress induces ephrin-B2 expression in PDL fibroblasts, and ephrin-B2-EphB4 interactions induce osteoblastogenesis in osteoblasts of the alveolar bone. Conclusion: Ephrin-B2-EphB4 signaling between PDLF and osteoblasts of the alveolar bone might contribute to bone remodeling during orthodontic tooth movement. Significance: Understanding the regulation of bone remodeling during orthodontic tooth movement is a prerequisite for pharmacological interventions.
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